EP2212976B1 - Surge arrester having thermal overload protection - Google Patents

Abstract

An overvoltage arrester includes at least two electrodes and a melt element that connects one of the electrodes to an outer terminal of the overvoltage arrester. An extinguishing device is designed to extinguish an electric arc.

Description

The invention relates to a surge arrester with thermal overload protection and its use and a method for protecting a surge arrester from thermal overload.

From the DE 102005036265 A1 a surge arrester is known.

The publication US 5,198,791 A describes an overvoltage protection device having a two-electrode overvoltage protection element connected via lead wires, fuses and a spring with external terminals. When the device is triggered, one of the fuses melts and the spring contracts toward one of the outer terminals, thereby disconnecting the overvoltage protection element from the circuit.

An object to be solved is to provide a thermal overload protection for a surge arrester and a method that safely and easily protect the surge arrester from thermal overload. Furthermore, a use must be specified.

This object is achieved in the surge arrester with the features of claim 1, when used with the features of claim 11 and in the method with the features of claim 12.

The surge arrester has at least two electrodes; it can be a two-electrode as well as a three-electrode surge arrester. The surge arrester forms an interior space by means of a tubular insulator, preferably a ceramic cylinder, and external electrodes or external connections arranged at its front ends. In the interior, the at least two electrodes are soldered or welded to the external terminals and are typically opposite to each other as pin electrodes or as a tube electrode and Pen electrode, which projects into the tube electrode is formed. The interior of the surge arrester is gas-tight against the environment and contains a gas.

Surge arresters are used in particular to short-circuit high pulse-shaped voltages of a few kV and currents of a few kA in a very short time or to discharge them to ground. A prolonged load in the event of a fault, for example when a mains current is short-circuited via power supply network or via a telecommunication network or a voltage arrester (power cross), can lead to an inadmissibly high heating of the surge arrester, which possibly leads to a fire. On the other hand, a surge arrester is thermally stressed under a load with direct or alternating voltages or with direct or alternating currents. This case can sometimes also occur in lightning protection applications. Surge arresters in the field of network protection, for example in the power supply of buildings, serve to protect the network against lightning impulse currents and against overvoltages.

Inside the surge arrester, arcing occurs when a certain threshold voltage is exceeded. The arc is maintained by the feeding current as long as the electrical conditions for the arc are met. The arc creates a thermal load on the surge arrester that must not exceed specified values for the surge arrester and its installation environment. Inadmissibly high temperatures may cause the surge arrester to catch fire.

One of the at least two electrodes of the surge arrester is normally connected to the associated external terminal of the surge arrester by means of a fusible element under normal operating conditions. The fusible element establishes an electrical contact and mechanically connects the electrode to the external connection.

The surge arrester further includes an extinguishing device arranged to extinguish an arc. The arc either burns when the surge arrester responds between the two electrodes, or develops between the one electrode and the outer terminal when the fuse contacts and melts. The extinguishing device is triggered by the melting of the fusible element at too high a thermal load. The extinction of the arc is accomplished by extending the distance that the arc can travel or travel from one electrode to the other electrode or to the outer electrode of the surge arrester. By extinguishing the arc, the electrical circuit that is closed in the arc flashover between the electrodes of the surge arrester and the voltage or current source connected to the external electrodes is separated. As a result, a circuit is interrupted, so that no further thermal load occurs.

The surge arrester with extinguishing device is set up so that the external integrity of the surge arrester is maintained even when the extinguishing device is triggered. External integrity means that the housing assembly of the surge arrester remains intact and no Parts that could cause damage outside the surge arrester are detached or blown off. The extinguishing device is preferably arranged completely inside the housing of the surge arrester.

The extinguishing of the arc prevents overheating of the overvoltage arrester due to thermal overload and causes the surge arrester to catch fire. At the same time, it is possible that an arc-extinguishing gas or medium from the outer region of the surge arrester flows into the interior of the surge arrester or in the vicinity of the extinguishing device and an arc generated by the separation process is deleted.

In an advantageous embodiment, the melting element has the properties of a low-melting solder. As alternatives, a soft solder or a braze can be used. This ensures that, in the event of a thermal load on the surge arrester, the solder of the melting element is first melted before the remaining elements of the surge arrester can be damaged. The melting solder triggers the extinguishing device and an existing or resulting from the melting arc is deleted.

In a preferred embodiment, the fusible element is configured to melt upon inadmissible heating and to cause the erasing device to move the one electrode to a position farther from the other electrode of the surge arrester, or to increase the distance formed therebetween. This embodiment makes it possible, by the movement of the one electrode not only to ensure an extension of the distance between these two elements with respect to the other electrode, but also to move out the one electrode from the interior of the surge arrester so that it is safely inoperative. This achieves a particularly efficient protection against thermal overloading of the surge arrester and the device protected by it.

In another preferred embodiment, the fusible element is configured to melt when heated and to cause the erasing device to move an insulating member between the outer terminal and the one electrode. Preferably, the one electrode is formed in several parts and contains, in addition to the main electrode of the actual surge arrester, an auxiliary electrode with which the electrode is fixed in the surge arrester. Furthermore, the electrode has a pin pointing away from the interior of the surge arrester, which pin is electrically connected to the outer electrode by means of the fuse element. The fusible element is formed so that a gap is formed between the outer electrode and the one electrode connected thereto. In the case of an inadmissible heating of the surge arrester and a melting of the fusible element, an insulation element is moved in this gap, so that the connection between the external connection and the one electrode is separated and interrupted.

In a particularly preferred embodiment, the extinguishing device has a spring with which the movements required for the insulation are implemented. The spring has the advantage that on the one hand the melting element mechanically biased and upon release of the fusible element by a relaxation of the spring an efficient movement of the leading electrode or the insulating element is performed to perform the insulation. Depending on the design, the spring is provided as a compression spring or as a tension spring. However, a compression spring has the particular advantage that the spring support can be easily performed.

In a further particularly advantageous embodiment, the extinguishing device is arranged in a space separated from the electrode of the surge arrester not connected to the fusible element. This embodiment makes it possible on the one hand optimally optimize the interior of the actual surge arrester formed by the electrodes and the insulator to the specifications of the surge arrester. On the other hand, the separated space accommodating the extinguishing device can be optimally designed for the function to be performed by the extinguishing device. For example, it is possible to use materials for the separated space and the extinguishing device, which can withstand an arc generated in the separation process or the arc in the process of extending the electrode gap without being ignited. Furthermore, the separated space may contain a gas or a medium, which helps in triggering the melting element or the use of the extinguishing device to extinguish the resulting arc as efficiently as possible.

In an embodiment in which the one electrode of the surge arrester by means of the extinguishing device of the other electrode is removed, the spring is particularly preferably designed as a compression spring, which is biased in the normal state, ie without response of the fusible element between the outer terminal and the one electrode. This makes it possible that when melting the fusible element, the spring relaxes and pulls the electrode from the interior of the surge arrester by this movement and separates from the outer terminal.

In an embodiment in which an insulating element is moved between the one electrode and the outer terminal in the case of triggering of the fusible element, it is particularly advantageous to provide a support for a compression spring on the outer electrode in such a way that the compression spring relaxes in the event of triggering of the fusible element and the insulating element between which moves one electrode and the outer terminal. In this case, the shape of the insulating element is adapted to the shape of the electrode. In a pin electrode, the insulating member preferably has the shape of a pot, the walls of which move between the pin electrode and the outer terminal and presses against the bottom of the compression spring.

In modified embodiments, an embodiment of the spring is provided as a tension spring.

With molten melting element, it is possible to actuate a contact element upon reaching the end position after the movement of the one electrode. By the spring and the contact element, an electrical contact is closed and generates an electrical signal. This electrical signal can be used for further processing, be used for example to display the functional state of the surge arrester.

With particular advantage, the surge arrester can be used in a device which places high demands both on proper functioning and against thermal and other stresses. These include, for example, a power supply network, e.g. in a building, or a telecommunications device or a telecommunications network, which can be efficiently protected against lightning and other overvoltages by the surge arrester. The surge arrester is not limited in its use and can also be used in any other electrical circuit in which high voltages must be dissipated by means of a surge arrester.

In a method for protecting a surge arrester as described above from thermal overload, the following steps are provided. If the surge arrester heats up excessively, the surge arrester heats up on the melting element, which is designed so that it melts when the thermal load is unduly high, before other parts of the surge arrester can catch fire. As a result of the melting of the fusible element, in a next step, an extinguishing device is triggered, which extends a path extending from one electrode of the surge arrester to the other electrode of the surge arrester or to the outer electrode. The extension of the route is effected in that in a preferred method step, the electrode is moved away from the other electrode and is further away in its end position. there the external integrity of the surge arrester is maintained.

In another preferred method step, an insulating element is moved into a space between the one electrode and the outer electrode with the aid of the extinguishing device. The one space is formed by melting of the fusible element and released for the movement of the insulating element.

In a further preferred method step, upon melting of the fusible element with the aid of the extinguishing device, a contact element is activated which generates an electrical signal and forwards it to a display or control device.

The arrangement and the method are explained in more detail below with reference to exemplary embodiments and associated figures. The embodiments illustrated in the figures of the drawing are not to be construed as true to scale and shown purely schematically to explain the elements and the method. Identical elements or elements with the same function are provided with the same reference numerals.

Figur 1

einen Überspannungsableiter gemäß einer ersten Ausführungsform im Normalzustand und nach einer Auslösung der Löschvorrichtung,

Figur 2

einen Überspannungsableiter gemäß einer zweiten Ausführungsform im Normalzustand und nach einer Auslösung der Löschvorrichtung.

Show it:

FIG. 1

a surge arrester according to a first embodiment in the normal state and after a triggering of the extinguishing device,

FIG. 2

a surge arrester according to a second embodiment in the normal state and after a release of the extinguishing device.

FIG. 1 schematically shows a first embodiment of a surge arrester. FIG. 1a shows the normal state and FIG. 1b the state after triggering the extinguishing device.

According to FIG. 1a For example, the surge arrester has an interior 10 as a discharge space, which is formed by a tubular insulator 11 and two outer electrodes 12 and 13 integrally formed on the outer sides of the insulator. As a discharge path, the interior of the surge arrester includes a tubular electrode 14 which is connected to the outer electrode 13 and a pin electrode 15 projecting into the tubular electrode 14, which is connected to the outer electrode 12.

The outer electrode 12 is formed cup-shaped and protrudes with its cup into the interior 10 of the surge arrester. The cup bottom contains a hole 16 through which the inner electrode 15 is guided. Outside the inner space 10, the electrode 15 has a head 17 whose outer diameter is greater than the inner diameter of the hole 16. The electrode 15 with head 17 is connected to the outer terminal 12 by means of a fusible element 18.

The melting element 18 is preferably designed as a soft solder or brazing alloy, so that in the normal state shown there is a good electrically conductive connection between the electrode 15 and the outer electrode 12. The fusible element is designed such that it covers the bottom of the cup and optionally enters into the hole 16 of the outer electrode 12. The the Interior 10 facing side of the head 17 of the electrode 15 is full on the cup bottom, so that the electrode 15 is guided exactly in the interior.

The head 17 has on the side facing away from the interior 10 of the electrode 15, a pin 19, on which a receptacle 20 is screwed. Between the receptacle 20 and the outer electrode 12, a compression spring 21 is arranged, which is supported against both the electrode 12 and the receptacle 20. In the exemplary embodiment, the receptacle 20 is guided in a tube 24 which is closed on the one hand by the electrode 12 and on the other hand by a connection 22. The terminal 22 is also cup-shaped and protrudes with its cup bottom in the interior 23 inside. The pin 19 of the electrode 15, the receptacle 20 and the compression spring 21 form the extinguishing device in connection with the melting element.

According to FIG. 1b the surge arrester is shown after tripping the melter. It can be seen that the melting element 18 has melted and the electrode 15 has been moved out of the interior 10 of the surge arrester by the force of the spring 21. As a result of the melting of the melting element 18, the compression spring 21 is in accordance with the pretensioned position FIG. 1a in a relaxed position according to FIG. 1b passed. The movement of the electrode 15 out of the interior 10 of the surge arrester is captured by the terminal 22, which forms a contact or closes in conjunction with the spring and the outer electrode. The distance formed between the two electrodes of the surge arrester or their spacing is thus extended so that the arc formed is extinguished.

In principle, it is not necessary for the extinguishing device to be guided in a separate outer space 23, as long as constructive measures are taken to ensure that, when the extinguishing device is triggered, the external integrity of the surge arrester is maintained and no parts are removed. The device of the cylindrical tube 24 and the terminal 22 is useful, however, because on the one hand uncontrolled movement of the electrode 15 is avoided from the surge arrester out. On the other hand, it is possible to fill the inner space 23 with a gas or a medium which, when the electrode 15 moves into the space 23, flows through the opening 16 formed in the interior of the surge arrester 10 and helps to form an arc between the electrode 15 and the electrode 14 to extinguish.

According to FIG. 2a As before, a surge arrester by means of an insulating tube 11, preferably made of ceramic or plastic, and an outer electrode 13 is formed. The outer electrode carries in the interior 10 of the surge arrester, an electrode 14 which is tubular in the embodiment, but may also be pin-shaped. The counter electrode 30 to the electrode 14 is constructed in several parts. It contains in the interior of the surge arrester the pin electrode 31, which projects into the tube electrode 14. Alternatively, the two electrodes 14 and 31 may be implemented as opposed pin electrodes.

The interior 10 of the surge arrester is closed by an auxiliary electrode 32, which is cup-shaped and the cup bottom protrudes into the interior 10 and the pin electrode 31 carries. The pin electrode 31 is soldered or welded to the center electrode 32, for example. On the side facing away from the interior 10, the electrode 30 has a pin 33 with a head 34. The head 34 is adapted to fit within the cup of the center electrode 32 and be soldered or welded thereto. The pin 33 or the electrode member 33 formed as a pin electrode is surrounded by an insulating tube 35 which is arranged between the center electrode 32 and an outer electrode 36 of the surge arrester.

The outer electrode 36 is shaped so that on the one hand enables a tight connection with the insulating tube 35 and on the other hand has a central hole 37 whose diameter is greater than the diameter of the pin 33 of the electrode 30. The insulating tube 35 preferably has the same outer and inner diameter as the insulating tube 11 of the actual discharge path of the surge arrester. However, it is not necessary that the insulating tube 35 must be made of the same material as the insulating tube 11. However, the insulation tube 35 is preferably also a ceramic tube.

On the side facing away from the insulating tube 35, the outer electrode 36 has an edge 38, are formed by the two paragraphs of the outer electrode 36. The outer shoulder allows the attachment of a housing part 39, which is provided as a holding device for the spring of the extinguishing device. In a tension spring, the housing part 39 may also be omitted. The interior of the facing paragraph of the outer electrode 36 receives a solder pad 40. The Surface of this paragraph is aligned with the bottom of the pin 33, which is opposite to the head 34.

The solder disk 40 is designed so that it connects the shoulder of the outer electrode 36 with the pin 33 of the one electrode 30 electrically good. On the space or gap 37, which is formed between the outer electrode 36 and the pin 33 of the one electrode, externally presses a Isoliertopf 41. The pot 41 has an edge thickness which is at most equal to the difference of the outer diameter of the pin 33 to the inner diameter of the outer electrode 36 may be. Between the bottom of the Isoliertopfes 41 and the outer housing 39, a compression spring 42 is tensioned, which biases the insulating element 41 against the fusible element 40 in the normal state shown. In the exemplary embodiment shown, the insulation pot 41 has an extension 43, which does not extend over the entire edge of the pot, and which extends through the melting element 40 into the space 37 between the outer electrode and the inner electrode 30. This extension allows, in the case of melting of the fusible element, that the insulating element 41 is guided on the pin 33 and can not tilt.

According to FIG. 2b the insulating element 41 is pushed in the tripped state of the fusible element by means of the relaxing spring 42 via the pin 33 of the one electrode of the surge arrester or in the hole of the outer electrode. Thereby, the available for an arc free path between the outer electrode 36 is extended by the one electrode of the surge arrester. In this embodiment, even when the melting element is triggered, the interior space 10 of the surge arrester is completely retained.

A resulting from the separation of the one electrode 30 and the outer terminal 36 arc is deleted on the one hand by the long isolation paths of the insulating element 41. However, it is also possible to fill the inner space formed between the insulating tube 35 and the pin 33 of the one electrode with a gas or a material that supports the arc extinguishing in an arc.

The description of the specified objects and methods is not limited to the individual specific embodiments. Rather, the features of the individual embodiments, as far as technically feasible, can be combined as desired. Thus, the described object and the method can be realized, for example, with a tubular electrode instead of a pin electrode.

LIST OF REFERENCE NUMBERS

10

inner space

11

insulating tube

12, 13, 36

external connection

14, 15, 30

Electrodes of the surge arrester

16, 37

Hole of an outer electrode

17

Head of an electrode

18, 40

fuse

19, 33

External tap of an electrode of the surge arrester

20

admission

21, 42

compression spring

22

Connection of the extinguishing device

23

Interior of the extinguisher

24

tubular insulating part

31

Inner electrode of an electrode

32

Center electrode of an electrode

33

Outer pin of an electrode

34

Head of an outer pin of an electrode

35

insulation body

38

Edge of an outer electrode

39

casing

41

insulation element

43

Extension of the edge of the insulation element

Claims (15)

1. Surge arrestor having

   - at least two mutually isolated electrodes (14, 15; 14, 30), which are respectively connected to an external connection (12, 13; 13, 36), having

   - a fusible element (18; 40), which connects a first of the at least two electrodes (15; 30) to a first external connection (12; 36) of the surge arrestor, and having

   - a quenching apparatus (19, 20, 21; 41, 42), which is initiated by melting of the fusible element and is designed to quench an arc,

   characterized in that a path which originates from the first (15) of the at least two electrodes is lengthened to the second (14) of the at least two electrodes, or in that a path which originates from the first (30) of the at least two electrodes is lengthened to the first external connection (36) by means of an isolation element (41).
2. Surge arrestor according to Claim 1,
   wherein the external integrity of the surge arrestor is maintained when the quenching apparatus has been initiated.
3. Surge arrestor according to Claim 1 or 2,
   wherein the quenching apparatus can move the first (15; 30) of the at least two electrodes to a position further away from the second (14) of the at least two electrodes.
4. Surge arrestor according to one of Claims 1 to 3,
   wherein the quenching apparatus has a spring (21; 42) which is supported against a receptacle (20) of the one electrode (15) and loads the fusible element (18) in tension.
5. Surge arrestor according to Claim 4,
   wherein the spring is in the form of a compression spring which is pre-stressed between the one of the two external connections (18) and the first electrode (15).
6. Surge arrestor according to Claim 1 or 2,
   wherein the quenching apparatus can move the isolation element (41) to a position between the first external connection (36) and the first electrode (30).
7. Surge arrestor according to Claim 6,
   wherein the isolation element is in the form of a pot, with the wall being movable with the aid of a spring (42) between the first electrode (30) and the first external connection (36).
8. Surge arrestor according to Claim 7,
   wherein the spring (42) is supported against a holder (39) and the isolation element (41), the isolation element loading the fusible element (40) in compression at its free end.
9. Surge arrestor according to one of the preceding claims,
   wherein the fusible element is designed to melt when heated and to release a gas with arc-quenching characteristics.
10. Surge arrestor according to one of the preceding claims,
    wherein the quenching apparatus is arranged in an area (23; 39) which is separated from the second of the at least two electrodes.
11. Use of a surge arrestor according to one of Claims 1 to 10 in a power supply system or in a telecommunications device.
12. Method for protection of a surge arrestor according to one of Claims 1 to 10 against thermal overloading, having the following steps:

    - initiation of the quenching apparatus by melting of the fusible element when a thermal overload occurs,

    - lengthening of a path, which is formed from the second of the at least two electrodes of the surge arrestor to the first of the at least two electrodes of the surge arrestor, or lengthening of a path, which originates from the first of the at least two electrodes, to the first external connection by means of an isolation element,

    - maintenance of the external integrity of the surge arrestor.
13. Method according to Claim 12,
    wherein the path is lengthened by a relative movement between the first electrode and the second electrode of the surge arrestor.
14. Method according to Claim 12 or 13,
    wherein a contact element which produces an electrical signal is activated.
15. Method according to Claim 12,
    wherein the path is lengthened by movement of the isolation element into an area which was released by the melted fusible element.

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